View clinical trials related to Brain Injuries.
Filter by:The goal of this clinical trial is to evaluate GetUp&Go, a program for promoting increased physical activity in individuals at least 6 months post moderate-to-severe traumatic brain injury. GetUp&Go is a remotely delivered 10-week program that includes one-on-one sessions with a therapist and a mobile health application (RehaBot). The main question is whether participants in the 10-week GetUp&Go program increase their physical activity, and exhibit associated benefits in mental and physical health, relative to those who are put on a waitlist. - Question 1: Do participants who receive immediate treatment with GetUp&Go show more increased physical activity, measured by accelerometer activity counts per day, and improve more on secondary outcomes, such as self-reported physical activity, emotional function, fatigue, sleep, pain, and health-related quality of life, compared to their baseline, relative to those who are put on a waitlist? - Question 2: Do participants who have continued access to the mobile health component of the intervention, RehaBot, show better maintenance of physical activity gains compared to those who no longer have access to RehaBot? - Question 3: Are individual participant characteristics associated with participants' response to the treatment program?
Extreme prematurity is constantly increasing according to the World Health Organization. However, methods to train premature infants at risk of disability is sorely lacking. The goal of this project is to overcome this problem. In previous studies, the investigators discovered that promoting the crawling of typical newborns on a mini skateboard, the Crawliskate (a new tool that the investigators designed and patented EP2974624A1), is an excellent way to stimulate infants' motor and locomotor development. This method is a promising way to provide early interventions in infants at heightened risk for developmental delay, such as premature infants. The specific objective of this study is to determine if early training in crawling on this mini skateboard will accelerate motor (particularly locomotor) and/or neuropsychological development in very premature infants identified as high risk for developmental delay. Methodology: The investigators will study and follow two groups of very premature infants born between 24 and 26 weeks of gestational age or born between 26 and 32 with major brain lesions. These infants will be recruited before their hospital discharge at the NICU. After their discharge from the hospital, one group of infants will be trained at home by their parents under the supervision of physiotherapists to crawl on the Crawliskate every day for 2 months (Crawli group), and one group of infants will receive regular medical care (Control group). All infants will be tested for: 1)their crawling proficiency on the Crawliskate at term-equivalent age (just before training for the trained groups) and at 2 and 6 months corrected age (CA, i.e., age determined from the date on which they should have been born), 2) their motor proficiency between 2 and 12 months CA (2D and 3D recording of head control, sitting, crawling, stepping, walking) and 3) their neurodevelopmental, motor and neuropsychological development between 0 and 28 months CA: BSID III edition, ASQ-3, Amiel-Tison's Neurological Assessment, Prechtl Assessment of general movements. One more ASQ-3 questionnaire will be provided at five years. Expected results: The first research hypothesis is that premature infants trained daily to crawl (for two months after discharge from the NICU) will acquire proficient crawling patterns and develop earlier and more effective motor and neuropsychological development than premature infants who receive no training.
The goal of this research project is to develop a tele-rehabilitation programme, which will constitute an original care pathway for brain damaged patients. It will aim to improve their impairments, activities and social participation. The programme will deliver a therapeutic education and self-education programme targeting the upper and lower limbs, and will assess the patients by means of a diary and self-evaluation questionnaires.
The investigational device used in this clinical investigation, the Nurochek PRO System (NCPRO), is a portable electroencephalogram (EEG) headset which delivers a visual stimulus and measures a VEP. The visual stimulus is delivered to the subjects' eyes via light-emitting diodes, and the EEG measures the user's visual-evoked potential. This headset communicates with an application on a computer, which processes the signals and transmits them to a secure cloud server for analysis and storage of the data. Nurochek PRO is a development of the previously FDA cleared Nurochek System. The primary objective of this clinical investigation was to evaluate the performance of the investigational device (NCPRO) against clinical diagnosis of detection of mild traumatic brain injury (mTBI). The primary endpoint outlined for this study was set at the collection of 100 valid investigational device readings from individuals with concussion and 500 valid investigational device readings from healthy individuals who have had a plausible mechanism of sustaining a concussion, but do not have one. Additionally, readings from healthy individuals are also to be acquired. The aim of this study was to collect data from 100 readings from individuals with concussion. The initial assumption was that sites would provide players pre-season and make players available for testing post-concussion. In practice, some sites provided player data only post-concussion event (such as medical clinics). Participants were acquired from sporting clubs, medical clinicals and schools.
Background: Cerebrovascular accident [CVA or commonly known as stroke] and traumatic brain injury (TBI) are common causes of morbidity, and motor impairments. Many stroke and TBI patients encounter severe functional impairments of their arm and/or hand. Recent studies have indicated that robotic training can improve upper limb function by enabling repetitive, adaptive, and intensive training. One type of robotic training is error enhancement during three-dimensional movements. The goal of this approach is to elicit better accuracy, stability, fluidity and range of motion during reaching. Previous research indicated the potential of robotic training with error enhancement as a viable clinical intervention for individuals facing motor deficits. Objectives: To evaluate the safety and efficacy of a new robotic system based on error enhancement and intended for rehabilitation of motor hand functions of post-stroke and TBI patients. Methods: A randomized, multi-center study with an open-label design. The study sample will consist of 96 participants who will be randomized into 2 separate groups. The intervention group consisting of 48 patients will receive training with the new robotic system, while the control group consisting of additional 48 patients will receive only standard practice treatments (with no exposure to the new robotic system). The outcomes of safety (adverse events and treatment tolerability), and efficacy (motor function, speed, tone, and spasticity) will be assessed and compared between the two groups. The assessment of the outcomes will be conducted at four different time points: (1) prior to the initiation of the four-week intervention, (2) after 2 weeks of intervention, (3) at the conclusion of the intervention, and (4) at a three-month follow-up session.
The purpose of this randomized controlled trial is to evaluate whether the InMotion intervention, delivered via telehealth (using a HIPAA-compliant video platform or phone), which uses evidence-based behavioral and motivational counseling to increase daily physical activity, is an effective treatment for Major Depressive Disorder (MDD) for people who are at least one year out from sustaining a traumatic brain injury (TBI). The first aim is to compare the efficacy of the InMotion intervention to the waitlist control (WLC) condition on measures of depression severity and associated conditions in under-active adults with TBI and MDD. For the second aim the investigators plan to identify possible moderators of exercise treatment effects. The third aim will examine possible mediators of treatment outcome. In addition, the weekly dose of exercise, the extent to which exercise generates positive affect, and engagement in enjoyable or meaningful aspects of life will be explored.
The aim of this study is to describe the quality of life of CT patients in our study, at least 6 months after the occurrence of the trauma. This assessment is related to the patient's degree of sequelae, using the GOSE scale.
The goal of this clinical trial is to evaluate the effects of Lifebloom One in people who have suffered a stroke or a traumatic brain injury. The main questions to be answered are: - Does Lifebloom One allow users to spend more time standing each day? - Does Lifebloom One allow users to improve their balance and gait? Participants will use Lifebloom One during 8 weeks. For each participant, gait and balance are compared either with and without Oxilio or before and after Lifebloom One intervention.
Hand motor and sensory impairments resulting from neurological disorders or injuries affect more than 50 million individuals worldwide. Conditions such as stroke, spinal cord injury (SCI), and traumatic brain injury (TBI) can cause long-term hand impairments, greatly impacting daily activities and social integration. Since traditional physiotherapy has limited effectiveness in rehabilitation, assistive devices helping in performing in daily activities have emerged as a necessary solution. Soft exoskeletons offer advantages as they are more comfortable and adaptable for the user, but they often struggle to generate sufficient force. On the other hand, electrical stimulation garments, like e-sleeves, show promise by stimulating nerves and muscles in the forearm. However, achieving precise and stable movement control remains challenging due to difficulties in electrode placement for targeted stimulation. Furthermore, none of the currently available devices are capable of artificially restoring lost sensation in users' hands, limiting their ability to manipulate with fragile objects. Recognizing these limitations, our study proposes a solution that combines a standard hand soft exoskeleton with: (i) electrical stimulation to the fingers' flexor and extensor muscles to generate artificial muscle contractions synchronized with the exoskeleton motion, compensating for the lack of gripping force, and (ii) electrical stimulation to the nerves to artificially restore the lost sensation of touch, enabling users to receive feedback on the force they are applying when interacting with the environment. The investigators refer to this proposed combination as Sensible-Exo. To achieve this goal, our project aims to evaluate the functional improvements in assistive and rehabilitative scenarios using SensoExo in comparison to use only the exoskeleton or having no support at all. The exoskeleton will be coupled with an electrical stimulating sleeve capable of delivering non-invasive electrical stimulation in the form of Functional Electrical Stimulation (FES) and Transcutaneous Electrical Nerve Stimulation (TENS). A glove with embedded force and bending sensors will be used to modulate the electrical stimulation. Additionally, apart from studying the enhancement of functional tasks, the investigators will explore improvements in body perception, representation, and multi-sensory integration. Indeed, the investigators also aim at identifying the way patients perceive their body by means of ad-hoc virtual reality assessments that has been developed. Before each assessment patient will perform some predefined movement in virtual reality to familiarize with it and increase embodiment. During the study, participants will perform a range of tasks based on their residual abilities, including motor tasks (e.g., grab and release, Toronto Rehabilitation Institute Hand Function Test, grip force regulation test, virtual egg test), cognitive tasks (dual tasks), and assessments of body representation and perception. Some of these tasks will be conducted in Virtual Reality environments, both with and without active stimulation.
This is a single-center, observational study. Patients after successful cardiopulmonary resuscitation (CPR) will be transferred to the emergency intensive care unit for further standardized management. After successful return of spontaneous circulation (ROSC) for 72h and hemodynamics remained stable for 24h, the post-resuscitated patients underwent functional magnetic resonance imaging (fMRI) examination. During the examination, the supervising physician accompanied the patient and monitored the patient's vital signs using a magnetic resonance monitoring system (Siemens Healthcare Prism, Germany). Patients who are on ventilators are mechanically ventilated using a magnetic ventilator (HAMILTON-MRI, USA). In additional to conventional sequences, fMRI is performed for diffusion-prepared pseudo-continuous arterial spin labeling (DP-pCASL) and blood oxygenation level dependent functional magnetic resonance imaging (BOLD-fMRI). These MRI sequences allow quantitative assessment of the patients' cerebral microcirculation, blood-brain barrier, and cerebral oxygenation status. Patients will be followed up for neurologic prognosis according to the Modified Rankin Scale (mRS) at 6 months after disease onset.